Proxy Apparatus and Method for Streaming Media Information and for Increasing the Quality of Stored Media Information

ABSTRACT

A proxy apparatus and method for streaming media information via at least one network and for building-up a good quality version of the media information are provided. When a user device communicates with the proxy apparatus using a particular bandwidth and requests that media information be provided, the proxy apparatus first determines if a version of the media information encoded for the user device&#39;s connection bandwidth has been stored in the proxy apparatus. If a version of the media information encoded for the user device&#39;s bandwidth is not available from the proxy apparatus, the proxy apparatus sends a request to a media server for the media information. If the version of the media information has missing packets, the proxy device sends retransmission requests to the media server to obtain the missing packets, thereby building-up a good quality version of the media information.

CROSS REFERENCE TO RELATED APPLICATIONS

This application is a continuation of and claims priority to pendingU.S. patent application No. Ser. 12/902,084, filed on Oct. 11, 2010,which is a continuation of U.S. patent application Ser. No. 12/163,242,filed on Jun. 27, 2008, now U.S. Pat. No. 7,831,780, which is acontinuation of U.S. patent application Ser. No. 10/676,485, filed onOct. 1, 2003, now U.S. Pat. No. 7,406,497, which is a continuation ofU.S. patent application Ser. No. 09/466,631, filed on Dec. 17, 1999, nowU.S. Pat. No. 6,651,103, which is a continuation-in-part of U.S. patentapplication Ser. No. 09/294,525, filed on Apr. 20, 1999, now U.S. Pat.No. 6,484,212, all of which are hereby incorporated by reference intheir entirety.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention provides a proxy apparatus and method forstreaming media information via at least one network and apparatus andmethods for increasing the quality of stored media information.

2. Description of Related Art

Currently, techniques are available to stream multimedia content from anetwork or media server. Streaming multimedia content involves sendingmultimedia content to a user's terminal buffer which then outputs themultimedia content for viewing by the user. The multimedia content maybe only temporarily stored on the user's terminal and is removed onceviewing is complete. Streaming multimedia content allows a user to beginviewing the content before it is completely sent to his/her terminal.

With present streaming techniques, a user must request multimediacontent from a local server normally across a network each time the userwishes to view the multimedia content. The user may experience largedelays and poor quality of service due to network congestion and networkutilization which will also impact other users that are making use ofthe network. Thus, there is a need for new technology to improvemultimedia content access.

SUMMARY OF THE INVENTION

The present invention provides a proxy apparatus and method forstreaming media information via at least one network. A user devicecommunicates with the proxy apparatus using a particular bandwidthconnection. When the user device requests media information, the proxyapparatus first determines if a version of the media information that isencoded for the user device's connection bandwidth is available in theproxy apparatus. If the version of the media information is available,then the media information is streamed to the user device directly fromthe proxy apparatus; otherwise the user device's request is forwarded tothe media server.

After the request is received, the media server streams a version of themedia information to the user device via the network and proxy device.The media information streamed to the user device is either the versionthat matches the bandwidth of the user device connection or a versionthat is encoded for the highest bandwidth less than the bandwidth of theuser device connection.

The proxy apparatus also requests from the media server some or allversions of the media information encoded for other bandwidths. Theseadditional versions, along with the version actually received by theuser device, are stored in a media storage device of the proxy device.Thus, when subsequent requests from user devices are received, the proxyapparatus acts as a proxy for the media server and streams a version ofthe media information that is either encoded for the particularbandwidth of the user device connection or a highest bandwidth less thanthe particular bandwidth of the user device connection without furtherinteraction with the media server.

During the streaming of media information and storage of the mediainformation in the media storage device, some data may be lost in thetransmission of the media information, i.e. data packets may be droppeddue to network congestion. The proxy device may maintain a listing, foreach version of the media information received, indicating the datapackets that were lost during the streaming of the media informationand/or may set a flag indicating that data packets were lost during thestreaming of the media information.

The proxy device, either immediately or at a later time, may sendrequests to the media server for the data packets that were lost duringthe streaming of the media information or for the entire mediainformation. This may be performed periodically, when network congestionlevels are minimal, or when other favorable conditions occur.Additionally, the lost data packets may be retrieved during subsequentrequests for the media information.

BRIEF DESCRIPTION OF THE DRAWINGS

The invention will be described with reference to the followingdrawings, wherein like numerals designate like elements, and wherein:

FIG. 1 is a functional block diagram of a system according to thepresent invention;

FIG. 2 is an example of a data structure identifying versions of mediainformation stored in the gateway of FIG. 1;

FIGS. 3-8 illustrate the data flow between the user devices, gateway anda media server of FIG. 1;

FIG. 9 is a functional block diagram of the gateway of FIG. 1;

FIG. 10 is an exemplary flowchart outlining a method of streaming mediainformation to a user device; and

FIG. 11 is a flowchart outlining an exemplary method of increasing thequality of stored media information when data packets are lost duringthe streaming of the media information.

DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS

FIG. 1 is a functional block diagram of a system 10 according to thepresent invention. As shown in FIG. 1, the system 10 includes aplurality of user devices 100-110, a gateway proxy device 115, a network120 and a plurality of network and/or media servers 125-135.

The user devices 100-110 communicate with at least one of the networkand/or media servers 125-135 via the network 120. The user devices100-110 may be any type of device that is capable of sending andreceiving communication signals over the network 120. For example, theuser devices 100-110 may be computers, WebTVs, personal digitalassistants (PDA), point of sale devices, and the like. The user devices100-110 send and receive communication signals to and from the network120 via the gateway proxy device 115 using either wired or wirelesstechnologies.

The gateway proxy device 115 may be any type of device that providesaccess to the network 120. For example, the gateway proxy device 115 maybe used by an Internet Service Provider (ISP) and may be a networkserver, and the like.

The network 120 may be a single network or a plurality of networks. Forexample, the network 120 may include a local telephone network (such asa Bell Atlantic telephone network), a long distance network (such as anAT&T long distance telephone network) or a company's proprietaryintranet. Thus, the types of networks that may be used may includecommunications networks, cable TV networks, the Internet, privateintranets, cellular communication networks, a local area network (LAN),a wide area network (WAN) and the like. The network 120 may also be anycombination of these types of networks.

One or more media servers 125-135 are in communication with the network120. The media servers 125-135 store media information that may bestreamed to a user device 100-110 via the gateway proxy device 115 andnetwork 120. The media information is streamed to the user devices100-110 via the network 120 and gateway proxy device 115 when the userdevices 100-110 request that the media information be transmitted tothem. The media information may be, for example, digitized video and/oraudio data and the like.

The media servers 125-135 have access numbers that identify the mediaservers 125-135 to the network 120. Thus, a user of a user device100-110 may communicate with a media server 125-135 by entering theaccess number via a user interface of the user device 100-110 andsending the access number to the network 120 via the gateway proxydevice 115. The access number may be, for example, an IP address, domainname, and the like.

The user devices 100-110 may communicate with the gateway proxy device115, network 120 and media servers 125-135 over connections that supportdifferent bandwidths. The user devices 100-110 may use any of aplurality of communication protocols such as TCP/IP, UDP, multicast,HTTP, and the like. The media servers 125-135 may store multipleversions of the media information where each of the versions is encodedfor a specific bandwidth or the media servers 125-135 may store genericmedia information and encode the media information for a requestedbandwidth on demand. Thus, depending on the particular bandwidth of theuser device connection, the media server 125-135 may transmit aparticular version of the media information.

The gateway proxy device 115 may determine the bandwidth of the userdevice connection based on the log-in process. For example, if a userdevice 100 communicates with the gateway proxy device 115 via a modemcapable of a bandwidth of 56K bits per second (K bps) and the useractually connects to the gateway proxy device 115 at a bandwidth of33.6K bps (due to the gateway bandwidth availability at log-in, forexample), then 33.6K bps is the bandwidth of the user device connection.

When a user device 100 communicates with the gateway proxy device 115using a particular bandwidth and sends a first request for mediainformation from a media server 135, for example, the gateway proxydevice 115 first determines whether a version of the media informationencoded for the particular bandwidth of the user device connection isstored in the gateway proxy device 115. If stored, the version of themedia information is transmitted to the user device 100 withoutinteraction with the media server 135. If not stored, the gateway proxydevice 115 sends a second request to the media server 135 for a versionof the multimedia information encoded for the bandwidth of the userdevice connection.

After the second request is received, the media server 135 determineswhether the requested version of the media information is available. Ifavailable, the media server 135 streams the version of the mediainformation to the user device 100 via the network 120 and gateway proxydevice 115. The media server 135 may either encode the media informationon the fly, i.e. encode a general version of the media information for arequested bandwidth on demand, or retrieve the requested version of themedia information that was encoded earlier from storage. If therequested version of the media information is not available, the mediaserver 135 streams a version for the highest bandwidth that does notexceed the bandwidth of the user device connection.

The gateway proxy device 115 may store the version of the mediainformation as the user device 100 receives the media information. Thegateway proxy device 115 may also send one or more third requests to themedia server 135 for other available versions of the same media. Thegateway proxy device 115 may determine which other versions of the mediainformation are available via a media information meta-tag associatedwith the media information, as will be described in more detail later.

In this way, the gateway proxy device 115 may store, in a media storagedevice 116, all versions of the media information available from themedia server 135. When subsequent first requests are received from userdevices 100-110, the gateway proxy device 115 may stream an appropriateversion of the media information (i.e. encoded bandwidth equal to orless than the requesting user device connection) without any furtherinteraction with the media server 135.

As shown in FIG. 2, the gateway proxy device 115 may maintain a datastructure 200 for identifying which versions of the media informationare stored in the media storage device 116. As shown in FIG. 2, the datastructure includes a field 201 for identifying the filenames of theversions stored, a field 202 identifying the bandwidths for which theversions are encoded, and a field 203 identifying a date of eachcorresponding file. As shown in FIG. 2, the filenames of the versions ofthe media information may be amended to reflect the bandwidth for whichthey are encoded. For example, news promotion media information may beencoded for a bandwidth of 56K bps and thus, have the file nameNEWSPROMO56.XXX. These fields are only illustrative and are not meant tobe limiting in any way. Other fields may be used in addition to or inplace of the fields shown in FIG. 2.

When the gateway proxy device 115 receives a request from a user device100 for media information encoded for a particular bandwidth, thegateway proxy device 115 may first search field 201 of the datastructure 200 for the filename requested and then search field 202 todetermine if the versions stored in the media storage device 116correspond to the bandwidth of the user device connection. If anappropriate version is identified, the gateway proxy device 115 maystream the media information to the user device 100 without contactingthe media server 135. The gateway proxy device 115 sends a secondrequest to the media server 135 for the requested version of the mediainformation only if an appropriate version is not identified.

The date stamp contained in the field 203 of the data structure 200indicates the date associated with each of the stored files and permitsthe gateway proxy device 115 to determine the age of the stored filesand when updates may be necessary. The date may be, for example, thedate of creation of the file on the media server.

Updates may also be necessary when new versions for additionalbandwidths become available. Thus, the gateway proxy device 115 mayupdate the data structure 200 periodically, for example. The update mayalso be performed using other techniques such as conditional GET featureof the HTTP protocol, for example. The conditional GET is described, forexample, in Web Proxy Servers, Ari Luotonen, Prentice Hall, 1998, pages158-161, which is hereby incorporated by reference. There are othertechniques for obtaining updates of media information known in the artthat may be used without departing from the spirit and scope of thepresent invention.

Additionally, the time stamp may be used to determine when to deletefiles to free storage space. A file may be flagged for deletion, forexample, when the file has not received a predetermined number of “hits”since it was received. The term “hit” in this context means an accessingby a user device or streaming to a user device. Furthermore, files maybe flagged for deletion if they have not received a predetermined numberof “hits” within a prescribed period of time. Other methods ofdetermining which files to flag for deletion may be used withoutdeparting from the spirit and scope of the present invention.

FIGS. 3-8 illustrate the data flow between the user devices 100-110,gateway proxy device 115 and a media server 135, for example. Forpurposes of illustration, it is assumed that each user device 100-110connects to the gateway proxy device 115 at a different bandwidth.

As shown in FIG. 3, a user device 100 sends a request for mediainformation at bandwidth BX to the gateway proxy device 115 via theconnection between user device 100 and the gateway proxy device 115. Therequest may be a signal to the gateway proxy device 115 requesting aparticular filename, for example. The filename may be entered by a userof the user device 100 via a user interface, such as a keyboard,pointing device, voice recognition, and the like, or it may be generatedautomatically when a user, for example, selects a hypertext link.

Next, as shown in FIG. 4, the gateway proxy device 115 checks its mediastorage device 116 to determine if a version of the media informationencoded for the bandwidth BX is available. If the media information forthe bandwidth BX is not available, the gateway proxy device 115 sends arequest for a version of the media information encoded for the bandwidthBX to the media server 135 as indicated by dotted arrow 118.

The request from the gateway proxy device 115 to the media server 135may be a signal that identifies the filename and the requestedbandwidth. Alternatively, the media server 135 may convert the filenameinto a filename representative of the bandwidth requested. For example,a filename MOVIE.XXX may be converted into MOVIE288.XXX to representthat the MOVIE.XXX file is requested for a bandwidth corresponding to abandwidth of 28.8K. The particular format of the request from thegateway proxy device 115 to the media servers 125-135 will depend on theparticular devices and protocols being used.

Furthermore, the user device 100, for example, may be operating using aparticular protocol such as HTTP, TCP/IP, and the like. Each protocolhas its varying degrees of reliability when streaming media information.Thus, the gateway proxy device 115 may use a different protocol whencommunicating with the media server 135 to ensure the highestreliability of streaming between the media server 135 and the gatewayproxy device 115. The gateway proxy device 115 will still use the userdevice 100 protocol when streaming the media information from thegateway proxy device 115 to the user device 100.

As shown by the dotted arrow 120 in FIG. 5, upon receiving the requestfor media information from the gateway proxy device 115, the mediaserver 135 streams the version of the media information encoded for thebandwidth BX to user device 100 via the gateway proxy device 115 asshown by dotted arrow 122. The transmission between the media server 135and the gateway proxy device 115 may be performed at a much higherbandwidth than BX. The gateway proxy device 115 may stream the mediainformation to the user device 100 at the bandwidth BX independent ofthe bandwidth of the transmission between the gateway proxy device 115and the media server 135. Alternatively, the streaming of the mediainformation from the media server 135 to the gateway proxy device 115may be performed at the bandwidth BX of the user device 100. In eithercase, the gateway proxy device 115 stores the version of the mediainformation encoded for the bandwidth BX in the media storage device 116as indicated by the dotted arrow 124.

Next, as shown in FIG. 6, the gateway proxy device 115 sends a request126 to the media server 135 for a version of the same media informationbut encoded for bandwidth BY. In response, the media server 135 streamsthe media information bandwidth BY to the gateway proxy device 115(dotted arrow 128) which is then stored in the media storage device 116(dotted arrow 130). Similarly, as shown in FIG. 7, the gateway proxydevice 115 sends a request 132 to the media server 135 for a version ofthe same media information but encoded for bandwidth BZ. The version forBZ is streamed to the gateway proxy device 115 (dotted arrow 134) andthe gateway proxy device 115 stores this version of the mediainformation in the media storage device 116 (dotted arrow 136).

When a user device 105, for example, requests that the media informationbe provided at bandwidth BY, as shown in FIG. 8, the gateway proxydevice 115 checks the media storage device 116 for a version of themedia information encoded for bandwidth BY. In this example, therequested version is found and thus retrieved from the media storagedevice 116 (dotted arrow 140) and streamed to the user device 105(dotted arrow 142) without interacting with the media server 135.

The media storage device 116 may be any type of media storage devicethat allows for the temporary or permanent storage of information thatmay be retrieved by the gateway proxy device 115. The media mediastorage device 116 may be a hard disk, magnetic tape, rewriteableCD-ROM, RAM, cache memory, and the like.

While FIGS. 3-8 describe the streaming process as having multiplerequests for versions of the media information being sent sequentially,the present invention is not limited to such a process. Rather, therequests for other versions of the media information may be sentsimultaneously to the media server with the initial request. Theserequests for other versions of the media information may be performed inthe background of the streaming of the media information to the userdevice 100, for example. Thus, the user of the user device 100 will notperceive the streaming and storing of the other versions of the mediainformation by the gateway proxy device 115.

FIG. 9 is a functional block diagram of the gateway proxy device 115according to one embodiment of the present invention. As shown in FIG.9, the gateway proxy device 115 includes a controller 801, a user deviceinterface 802, a network interface 803, a media media storage deviceinterface 804 and memory 805. These devices are in communication withone another over the control/data bus 806.

When a user device 100-110 sends a request for media information to thegateway proxy device 115, the controller 801 receives the request viathe user device interface 802 and determines if the requested mediainformation for the bandwidth of the user device 100-110 connection isstored in the media storage device 116. The controller 801 searches thedata structure 200 in memory 805 for a version of the media informationencoded for the user device 100-110 connection bandwidth. If a versionfor the bandwidth is located, the controller 801 streams the mediainformation from the media storage device 116, via the media storagedevice interface 804, to the user device 100-110 via the user deviceinterface 802.

If a version is not located, the controller 801 sends the request to theappropriate media server 135, for example, via the network interface803. The controller 801 then receives the media information for the userdevice connection bandwidth from the media server 135 via the networkinterface 803. The controller 801 streams the media information to theuser device 100-110 via the user device interface 802 and also stores acopy of the media information in the media storage device 116 via themedia storage device interface 804.

As referred to earlier, each version of the media information mayinclude a meta-tag that identifies the other versions of the mediainformation that are resident on the media server 135, for example. Themeta-tag may be, for example, a Hyper Text Transfer Protocol (HTTP)header, an HTML META element as described, for example, in World WideWeb Programming with HTML & CGI, Tittel et al., IDG Books Worldwide,Inc., 1995, pages 70-71, which is hereby incorporated by reference, andthe like. Thus, when the gateway proxy device 115 receives the firstversion of the media information that is requested by the user device100, for example, the controller 801 reads the meta-tag information andidentifies the other versions of the media information stored on themedia server 135. Based on this meta-tag information, the controller 801sends requests for all the other versions of the media information thatare resident on the media server 135.

When the other versions of the media information are received from themedia server 135, the gateway proxy device 115 stores them in the mediamedia storage device 116 via the media storage device interface 804. Thegateway proxy device 115 may send the requests for other versions andstore the other versions in the media storage device 116 as a backgroundprocess so that the streaming of the media information to the userdevice 100 is not affected.

FIG. 10 is a flowchart outlining one embodiment of an exemplary methodof streaming media information according to the present invention. Instep 1001, the controller 801 receives a request for media informationfrom a user device 100-110 and goes to step 1002. In step 1002, thecontroller 801 determines the bandwidth of the user device connectionand goes to step 1003.

In step 1003, the controller 801 determines if the requested version ofthe media information for the user device connection bandwidth (or alower bandwidth) is available from the media storage device 116. If acopy of the requested media information for the bandwidth is available,the controller 801 goes to step 1004; otherwise, the controller 801 goesto step 1005. In step 1004, the controller 801 streams the copy of therequested media information to the user device 100-110, goes to step1012 and ends.

In step 1005, the controller 801 sends a request to an appropriate mediaserver 125-135, for the media information at the required bandwidth andgoes to step 1006. In step 1006, the controller 801 receives therequested version of the media information from the media server 125-135and streams the media information to the user device 100-110, and storesthe received version in the media storage device 116. In step 1007, thecontroller 801 reads the meta-tag information of the media informationand goes to step 1009.

In step 1009, the controller 801 sends requests to the media server125-135 for the other versions of the media information identified inthe meta-tag information, and goes to step 1010. In step 1010, thecontroller 801 receives the other versions of the media information fromthe media server 125-135 and goes to step 1011. In step 1011, thecontroller 801 stores the other versions of the media information in themedia storage device 116, goes to step 1012 and ends.

With the above apparatus and method, the gateway proxy device 115operates as a proxy for the media servers 125-135 when media informationis requested. In this way, when a user device 100-110 requests mediainformation, the media information may be streamed to the user device100-110 more quickly and with the highest quality receivable with theuser device 100-110 connection.

Additionally, as the user devices 100-110 use higher bandwidths andthus, higher quality of media information, the quality of the mediainformation is improved. Furthermore, the retrieval of the otherversions of the media information may be performed in parallel with theretrieval of the user device 100-110 requested version of the mediainformation. The retrieval of the other versions may be performed in amanner that is not perceivable by the user of the user device 100-110.

During the retrieval of media information from the media servers125-135, some of the media information, i.e. some of the data packets,may be lost during the transmission of the data through the network 120to the gateway proxy device 115. The lost data packets decrease thequality of the media information in that some of the information will bemissing during streaming to the user devices 100-110. The inventionprovides apparatus and methods for increasing the quality of storedmedia information to correct for data packet loss.

When the media information is streamed to a user device 100-110 inresponse to a request for the media information, a copy of the mediainformation is stored on the gateway proxy device 115 for use with laterrequests for the same media information. In addition to the version ofthe media information requested, other versions of the media informationmay be retrieved and stored on the gateway proxy device 115. During thestreaming from the media server 125-135, the gateway proxy device 115may monitor the data packets received for each version of the mediainformation and maintain a listing of missing data packets for eachversion of the media information. The gateway proxy device 115 may alsoset a flag indicating that data packets are missing from the version ofthe media information.

As described in Stephen A. Thomas, IPng and the TCP/IPProtocols-Implementing the Next Generation Internet, Wiley ComputerPublishing, which is hereby incorporated by reference in its entirety,each data packet of the media information includes header informationthat identifies a sequence number of the data packet in the sequence ofdata packets for the media information sent by the media server 125-135.Furthermore, report data packets may be transmitted between the mediaserver 125-135 and the gateway proxy device 115 to determined the totalnumber of data packets in a sequence as well as the lost data packets.

The gateway proxy device 115 uses this header information and reportdata packets to maintain a listing of the data packets that were lostduring the streaming of the media information to the user device 100-110and/or to set a flag value for the media information indicating thatthere are missing data packets. Based on the listing of missing datapackets, the gateway proxy device 115 may send requests to the mediaserver 125-135 for retransmission of the missing data packets at a latertime. In this way, the gateway proxy device 115 may increase the qualityof stored media information by sending retransmission requests to themedia server 125-135 until all of the data packets for the mediainformation are received and stored by the gateway proxy device 115.

The retransmission requests may be performed immediately upon detectionof the lost data packets, may be performed in a periodic manner, or maybe performed at a later time when network congestion levels are below apredetermined threshold or when other favorable conditions occur. Forexample, the gateway proxy device 115 may check each version of themedia information every 3 hours to determine if all of the data packetshave been received for that version of the media information. If not,then a retransmission request may be sent to the appropriate mediaserver 125-135 requesting, by sequence number for example, the datapackets which are still missing.

Alternatively, the gateway proxy device 115 may periodically measure thenetwork congestion of the network 120 and may send a retransmissionrequest when the network congestion falls below a predeterminedthreshold. The gateway proxy device 115 may measure the networkcongestion level by pinging the media server 125-135 to determine thedelay in receiving a response from the media server 125-135. The delaymay be correlated to a network congestion level.

In response to the retransmission request, the media server 125-135 mayretransmit the requested data packets to the gateway proxy device 115.The gateway proxy device 115 stores the received data packets in theappropriate sequence and memory location with the already stored datapackets in the media storage device 116.

In another embodiment of the invention, the gateway proxy device 115 maysend a retransmission request to the media server 125-135 upon receiptof a subsequent request for the media information from a user device100-110. For example, if the gateway proxy device 115 already stores aversion of the media information that has missing data packets and arequest for that version of the media information is received, thegateway proxy device 115 may still send a retransmission request to themedia server 125-135.

The retransmission request may be for only the missing data packets ormay be for the entire media information. If the retransmission requestis for the entire media information, as the media information is beingstreamed to the user device 100-110, a copy of the media information maybe rewritten over the already resident media information in the mediastorage device 116. Thus, those data packets that already exist in themedia storage device 116 will be overwritten and those data packets thatwere missing in the already existent media information in the mediastorage device 116 will be inserted in the appropriate position. Thosedata packets that were present on the media storage device 116 and werenot retransmitted due to data packet loss in the retransmission willremain as the already present data packets. In this way, a good qualityversion of the media information may be built up by subsequent requestsfor retransmission of the media information.

FIG. 11 is a flowchart outlining an exemplary operation of the gatewayproxy device 115 when increasing the quality of stored mediainformation. As shown in FIG. 11, in step 1110, the controller 801checks a version of media information stored in the media storage device116 to determine if the version of media information have missing datapackets. This may be performed by determining if a listing of missingdata packets is associated with the version of media information,retrieving a value for a tag which is set to represent whether or notdata packets are missing in the media information, or the like.

In step 1120, if data packets are missing from the media information,control goes to step 1130; otherwise, control goes to step 1170 andends. In step 1130, the controller sends a retransmission request to theappropriate media server through network interface 803. As describedabove, this retransmission request may request only those data packetsthat were missing in the media information or may request that theentire version of the media information be retransmitted.

In step 1140, the controller 801 receives the retransmission from themedia server and goes to step 1150. In step 1150, the controller 801stores the retransmitted data packets in the media storage device 116 inthe appropriate memory positions of the version of the mediainformation. As described above, if the entire version of the mediainformation is retransmitted, this process may include writing overexisting media information in the media storage device 116 and fillingin the missing data packets during the rewrite process.

In step 1160, the controller 801 determines if there is more mediainformation in the media storage device 116 that needs to be checked formissing data packets. If so, control returns to step 1110; otherwise,control goes to step 1170 and ends.

In addition to the retransmission processes described above, the gatewayproxy device 115 may request retransmission of the entire version of themedia information and store the retransmitted version in addition to thealready stored version of the media information in the media storagedevice 116. Once the retransmitted version of the media information isstored in the media storage device 116, the controller 801 may comparethe number of missing packets for each of the retransmitted version andthe already stored version of the media information. The version thathas less missing packets may then be retained for future use while theversion with the greater number of missing packets may be deleted tofree-up storage space.

As shown in FIG. 9, the methods of this invention are preferablyimplemented on a programmed processor. However, the gateway proxy device115 can also be implemented on a general purpose or special purposecomputer, a programmed microprocessor or microcontroller and peripheralintegrated circuit elements, an ASIC or other integrated circuit, ahardware electronic or logic circuit such as a discrete element circuit,a programmable logic device such as a PLD, PLA, FPGA or PAL, or thelike. In general, any device on which a finite state machine capable ofimplementing the flowcharts shown in FIGS. 10 and 11 can be used toimplement the gateway proxy device 115 functions of this invention.

While this invention has been described with specific embodimentsthereof, it is evident that many alternatives, modifications, andvariations will be apparent to those skilled in the art. Accordingly,the preferred embodiments of the invention as set forth herein areintended to be illustrative, not limiting. Various changes may be madewithout departing from the spirit and scope of the invention.

What is claimed is:
 1. A method for streaming media information, themethod comprising: receiving, by utilizing instructions from memory thatare executed by a processor, a first version of the media informationbased on a determination that a second version of the media informationthat is encoded at a second bandwidth cannot be received, wherein thefirst version of the media information is received from a server basedon a meta tag that identifies versions of the media information that arepresent on the server; and streaming, to a device, the first version ofthe media information at a first bandwidth, wherein the second bandwidthdiffers from the first bandwidth.
 2. The method of claim 1, furthercomprising storing the first version of the media information receivedfrom the server.
 3. The method of claim 1, further comprisingdetermining a user bandwidth associated with a connection of the device.4. The method of claim 3, further comprising receiving the first versionof the media information when the user bandwidth associated with theconnection of the device is less than the second bandwidth.
 5. Themethod of claim 1, further comprising receiving, from the device, arequest for the media information.
 6. The method of claim 1, furthercomprising transmitting, to the server, a request for the first versionof the media information at the first bandwidth.
 7. The method of claim1, further comprising receiving, from the server, each of the versionsof the media information identified by the meta tag.
 8. The method ofclaim 1, further comprising generating a list of data packets lostduring the streaming of the first version of the media information tothe device.
 9. The method of claim 8, further comprising retransmitting,to the device, the data packets in the list.
 10. A system for streamingmedia information, the system comprising: a memory that storesinstructions; a processor that executes the instructions to performoperations, the operations comprising: identifying a plurality ofversions of the media information from a meta-tag, wherein the pluralityof versions of the media information include a first version of themedia information and a second version of the media information;streaming, in response to a request from a device, the first version ofthe media information when a user bandwidth associated with the deviceis greater than or equal to a first bandwidth but less than a secondbandwidth, wherein the first version of the media information is encodedat the first bandwidth; and streaming, in response to the request fromthe device, the second version of the media information when the userbandwidth associated with the device is greater than or equal to thesecond bandwidth, wherein the second version of the media information isencoded at the second bandwidth, wherein the second bandwidth is greaterthan the first bandwidth.
 11. The system of claim 10, wherein theoperations further comprise storing the first version of the mediainformation and the second version of the media information.
 12. Thesystem of claim 10, wherein the operations further comprise receivingthe request for the media information from the device.
 13. The system ofclaim 10, wherein the operations further comprise determining the userbandwidth associated with the device based on a connection between thedevice and the system.
 14. The system of claim 10, wherein theoperations further comprise receiving, from a server, each of theplurality of versions of the media information identified by themeta-tag.
 15. The system of claim 10, wherein the operations furthercomprise determining which data packets were lost during the streamingof the first version of the media information.
 16. The system of claim15, wherein the operations further comprising retransmitting the datapackets that were determined to be lost during the streaming of thefirst version of the media information.
 17. A system for streaming mediainformation, the system comprising: a memory that stores instructions; aprocessor that executes the instructions to perform operations, theoperations comprising: transmitting, to a gateway proxy device, a firstversion of the media information based on a determination that a userbandwidth associated with a device is less than a second bandwidthassociated with a second version of the media information, wherein thefirst version of the media information is transmitted based on a metatag that identifies versions of the media information that are presenton the system; and streaming, to the gateway proxy device, the firstversion of the media information at a first bandwidth, wherein the firstbandwidth is less than or equal to the user bandwidth.
 18. The system ofclaim 17, wherein the operations further comprise transmitting each ofthe versions of the media information identified on the system.
 19. Thesystem of claim 17, wherein the operations further compriseretransmitting data packets that were lost during the streaming of thefirst version of the media information.
 20. The system of claim 17,wherein the operations further comprise receiving, from the gatewayproxy device, a request for the first version of the media informationwhen the user bandwidth of the device is less than the second bandwidth.